/* Return a list of valid memory ranges */ int get_memory_ranges(struct memory_range **range, int *ranges, unsigned long kexec_flags) { /* allocate memory_range dynamically */ max_memory_ranges = 1; if (alloc_memory_ranges()) return -1; if (setup_memory_ranges(kexec_flags)) return -1; /* * copy the memory here, another realloc_memory_ranges might * corrupt the old memory */ *range = calloc(sizeof(struct memory_range), nr_memory_ranges); if (*range == NULL) return -1; memmove(*range, memory_range, sizeof(struct memory_range) * nr_memory_ranges); *ranges = nr_memory_ranges; dbgprintf("get memory ranges:%d\n", nr_memory_ranges); return 0; }
/* Return a list of valid memory ranges */ int get_memory_ranges_dt(struct memory_range **range, int *ranges, unsigned long kexec_flags) { if (count_memory_ranges()) return -1; if (alloc_memory_ranges()) return -1; if (setup_memory_ranges(kexec_flags)) return -1; *range = memory_range; *ranges = nr_memory_ranges; return 0; }
/* Return a list of valid memory ranges */ int get_memory_ranges(struct memory_range **range, int *ranges, unsigned long kexec_flags) { if (count_memory_ranges()) return -1; if (alloc_memory_ranges()) return -1; if (setup_memory_ranges(kexec_flags)) return -1; *range = memory_range; *ranges = nr_memory_ranges; fprintf(stderr, "get memory ranges:%d\n", nr_memory_ranges); return 0; }
int elf_ppc64_load(int argc, char **argv, const char *buf, off_t len, struct kexec_info *info) { struct mem_ehdr ehdr; char *cmdline, *modified_cmdline = NULL; const char *devicetreeblob; int cmdline_len, modified_cmdline_len; uint64_t max_addr, hole_addr; unsigned char *seg_buf = NULL; off_t seg_size = 0; struct mem_phdr *phdr; size_t size; uint64_t *rsvmap_ptr; struct bootblock *bb_ptr; unsigned int nr_segments, i; int result, opt; uint64_t my_kernel, my_dt_offset; unsigned int my_panic_kernel; uint64_t my_stack, my_backup_start; uint64_t toc_addr; unsigned int slave_code[256/sizeof (unsigned int)], master_entry; #define OPT_APPEND (OPT_ARCH_MAX+0) #define OPT_RAMDISK (OPT_ARCH_MAX+1) #define OPT_DEVICETREEBLOB (OPT_ARCH_MAX+2) #define OPT_ARGS_IGNORE (OPT_ARCH_MAX+3) static const struct option options[] = { KEXEC_ARCH_OPTIONS { "command-line", 1, NULL, OPT_APPEND }, { "append", 1, NULL, OPT_APPEND }, { "ramdisk", 1, NULL, OPT_RAMDISK }, { "initrd", 1, NULL, OPT_RAMDISK }, { "devicetreeblob", 1, NULL, OPT_DEVICETREEBLOB }, { "args-linux", 0, NULL, OPT_ARGS_IGNORE }, { 0, 0, NULL, 0 }, }; static const char short_options[] = KEXEC_OPT_STR ""; /* Parse command line arguments */ initrd_base = 0; initrd_size = 0; cmdline = 0; ramdisk = 0; devicetreeblob = 0; max_addr = 0xFFFFFFFFFFFFFFFFUL; hole_addr = 0; while ((opt = getopt_long(argc, argv, short_options, options, 0)) != -1) { switch (opt) { default: /* Ignore core options */ if (opt < OPT_ARCH_MAX) break; case '?': usage(); return -1; case OPT_APPEND: cmdline = optarg; break; case OPT_RAMDISK: ramdisk = optarg; break; case OPT_DEVICETREEBLOB: devicetreeblob = optarg; break; case OPT_ARGS_IGNORE: break; } } cmdline_len = 0; if (cmdline) cmdline_len = strlen(cmdline) + 1; else fprintf(stdout, "Warning: append= option is not passed. Using the first kernel root partition\n"); if (ramdisk && reuse_initrd) die("Can't specify --ramdisk or --initrd with --reuseinitrd\n"); setup_memory_ranges(info->kexec_flags); /* Need to append some command line parameters internally in case of * taking crash dumps. */ if (info->kexec_flags & KEXEC_ON_CRASH) { modified_cmdline = xmalloc(COMMAND_LINE_SIZE); memset((void *)modified_cmdline, 0, COMMAND_LINE_SIZE); if (cmdline) { strncpy(modified_cmdline, cmdline, COMMAND_LINE_SIZE); modified_cmdline[COMMAND_LINE_SIZE - 1] = '\0'; } modified_cmdline_len = strlen(modified_cmdline); } /* Parse the Elf file */ result = build_elf_exec_info(buf, len, &ehdr, 0); if (result < 0) { free_elf_info(&ehdr); return result; } /* Load the Elf data. Physical load addresses in elf64 header do not * show up correctly. Use user supplied address for now to patch the * elf header */ phdr = &ehdr.e_phdr[0]; size = phdr->p_filesz; if (size > phdr->p_memsz) size = phdr->p_memsz; hole_addr = (uint64_t)locate_hole(info, size, 0, 0, max_addr, 1); ehdr.e_phdr[0].p_paddr = hole_addr; result = elf_exec_load(&ehdr, info); if (result < 0) { free_elf_info(&ehdr); return result; } /* If panic kernel is being loaded, additional segments need * to be created. */ if (info->kexec_flags & KEXEC_ON_CRASH) { result = load_crashdump_segments(info, modified_cmdline, max_addr, 0); if (result < 0) return -1; /* Use new command line. */ cmdline = modified_cmdline; cmdline_len = strlen(modified_cmdline) + 1; } /* Add v2wrap to the current image */ seg_buf = NULL; seg_size = 0; seg_buf = (unsigned char *) malloc(purgatory_size); if (seg_buf == NULL) { free_elf_info(&ehdr); return -1; } memcpy(seg_buf, purgatory, purgatory_size); seg_size = purgatory_size; elf_rel_build_load(info, &info->rhdr, (const char *)purgatory, purgatory_size, 0, max_addr, 1, 0); /* Add a ram-disk to the current image * Note: Add the ramdisk after elf_rel_build_load */ if (ramdisk) { if (devicetreeblob) { fprintf(stderr, "Can't use ramdisk with device tree blob input\n"); return -1; } seg_buf = (unsigned char *)slurp_file(ramdisk, &seg_size); add_buffer(info, seg_buf, seg_size, seg_size, 0, 0, max_addr, 1); hole_addr = (uint64_t) info->segment[info->nr_segments-1].mem; initrd_base = hole_addr; initrd_size = (uint64_t) info->segment[info->nr_segments-1].memsz; } /* ramdisk */ if (devicetreeblob) { unsigned char *blob_buf = NULL; off_t blob_size = 0; /* Grab device tree from buffer */ blob_buf = (unsigned char *)slurp_file(devicetreeblob, &blob_size); add_buffer(info, blob_buf, blob_size, blob_size, 0, 0, max_addr, -1); } else { /* create from fs2dt */ seg_buf = NULL; seg_size = 0; create_flatten_tree(info, (unsigned char **)&seg_buf, (unsigned long *)&seg_size,cmdline); add_buffer(info, seg_buf, seg_size, seg_size, 0, 0, max_addr, -1); } /* patch reserve map address for flattened device-tree * find last entry (both 0) in the reserve mem list. Assume DT * entry is before this one */ bb_ptr = (struct bootblock *)( (unsigned char *)info->segment[(info->nr_segments)-1].buf); rsvmap_ptr = (uint64_t *)( (unsigned char *)info->segment[(info->nr_segments)-1].buf + bb_ptr->off_mem_rsvmap); while (*rsvmap_ptr || *(rsvmap_ptr+1)) rsvmap_ptr += 2; rsvmap_ptr -= 2; *rsvmap_ptr = (uint64_t)( info->segment[(info->nr_segments)-1].mem); rsvmap_ptr++; *rsvmap_ptr = (uint64_t)bb_ptr->totalsize; nr_segments = info->nr_segments; /* Set kernel */ my_kernel = (uint64_t)info->segment[0].mem; elf_rel_set_symbol(&info->rhdr, "kernel", &my_kernel, sizeof(my_kernel)); /* Set dt_offset */ my_dt_offset = (uint64_t)info->segment[nr_segments-1].mem; elf_rel_set_symbol(&info->rhdr, "dt_offset", &my_dt_offset, sizeof(my_dt_offset)); /* get slave code from new kernel, put in purgatory */ elf_rel_get_symbol(&info->rhdr, "purgatory_start", slave_code, sizeof(slave_code)); master_entry = slave_code[0]; memcpy(slave_code, info->segment[0].buf, sizeof(slave_code)); slave_code[0] = master_entry; elf_rel_set_symbol(&info->rhdr, "purgatory_start", slave_code, sizeof(slave_code)); if (info->kexec_flags & KEXEC_ON_CRASH) { my_panic_kernel = 1; /* Set panic flag */ elf_rel_set_symbol(&info->rhdr, "panic_kernel", &my_panic_kernel, sizeof(my_panic_kernel)); /* Set backup address */ my_backup_start = info->backup_start; elf_rel_set_symbol(&info->rhdr, "backup_start", &my_backup_start, sizeof(my_backup_start)); } /* Set stack address */ my_stack = locate_hole(info, 16*1024, 0, 0, max_addr, 1); my_stack += 16*1024; elf_rel_set_symbol(&info->rhdr, "stack", &my_stack, sizeof(my_stack)); /* Set toc */ toc_addr = (unsigned long) my_r2(&info->rhdr); elf_rel_set_symbol(&info->rhdr, "my_toc", &toc_addr, sizeof(toc_addr)); #ifdef DEBUG my_kernel = 0; my_dt_offset = 0; my_panic_kernel = 0; my_backup_start = 0; my_stack = 0; toc_addr = 0; elf_rel_get_symbol(&info->rhdr, "kernel", &my_kernel, sizeof(my_kernel)); elf_rel_get_symbol(&info->rhdr, "dt_offset", &my_dt_offset, sizeof(my_dt_offset)); elf_rel_get_symbol(&info->rhdr, "panic_kernel", &my_panic_kernel, sizeof(my_panic_kernel)); elf_rel_get_symbol(&info->rhdr, "backup_start", &my_backup_start, sizeof(my_backup_start)); elf_rel_get_symbol(&info->rhdr, "stack", &my_stack, sizeof(my_stack)); elf_rel_get_symbol(&info->rhdr, "my_toc", &toc_addr, sizeof(toc_addr)); fprintf(stderr, "info->entry is %p\n", info->entry); fprintf(stderr, "kernel is %lx\n", my_kernel); fprintf(stderr, "dt_offset is %lx\n", my_dt_offset); fprintf(stderr, "panic_kernel is %x\n", my_panic_kernel); fprintf(stderr, "backup_start is %lx\n", my_backup_start); fprintf(stderr, "stack is %lx\n", my_stack); fprintf(stderr, "toc_addr is %lx\n", toc_addr); fprintf(stderr, "purgatory size is %lu\n", purgatory_size); #endif for (i = 0; i < nr_segments; i++) fprintf(stderr, "segment[%d].mem:%p memsz:%ld\n", i, info->segment[i].mem, info->segment[i].memsz); return 0; }